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Physics–Dynamics Coupling with Element-Based High-Order Galerkin Methods: Quasi-Equal-Area Physics Grid

Herrington, Adam R. ; Lauritzen, Peter H. ; Taylor, Mark A. ; [et al.]

American Meteorological Society ; 2019

In: Monthly Weather Review Vol. 147, No. 1 ( 2019-01), p. 69-84

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In: Monthly Weather Review, American Meteorological Society, Vol. 147, No. 1 ( 2019-01), p. 69-84

Abstract: Atmospheric modeling with element-based high-order Galerkin methods presents a unique challenge to the conventional physics–dynamics coupling paradigm, due to the highly irregular distribution of nodes within an element and the distinct numerical characteristics of the Galerkin method. The conventional coupling procedure is to evaluate the physical parameterizations ( physics) on the dynamical core grid. Evaluating the physics at the nodal points exacerbates numerical noise from the Galerkin method, enabling and amplifying local extrema at element boundaries. Grid imprinting may be substantially reduced through the introduction of an entirely separate, approximately isotropic finite-volume grid for evaluating the physics forcing. Integration of the spectral basis over the control volumes provides an area-average state to the physics, which is more representative of the state in the vicinity of the nodal points rather than the nodal point itself and is more consistent with the notion of a “large-scale state” required by conventional physics packages. This study documents the implementation of a quasi-equal-area physics grid into NCAR’s Community Atmosphere Model Spectral Element and is shown to be effective at mitigating grid imprinting in the solution. The physics grid is also appropriate for coupling to other components within the Community Earth System Model, since the coupler requires component fluxes to be defined on a finite-volume grid, and one can be certain that the fluxes on the physics grid are, indeed, volume averaged.

Type of Medium: Online Resource

ISSN: 0027-0644 , 1520-0493

URL: Article

DOI: 10.1175/MWR-D-18-0136.1

RVK:

RA 1000

Language: English

Publisher: American Meteorological Society

Publication Date: 2019

detail.hit.zdb_id: 2033056-X

detail.hit.zdb_id: 202616-8

SSG: 14

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Assessing satellite‐derived start‐of‐season measures in the conterminous USA

Schwartz, Mark D. ; Reed, Bradley C. ; White, Michael A.

Wiley ; 2002

In: International Journal of Climatology Vol. 22, No. 14 ( 2002-11-30), p. 1793-1805

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In: International Journal of Climatology, Wiley, Vol. 22, No. 14 ( 2002-11-30), p. 1793-1805

Abstract: National Oceanic and Atmospheric Administration (NOAA)‐series satellites, carrying advanced very high‐resolution radiometer (AVHRR) sensors, have allowed moderate resolution (1 km) measurements of the normalized difference vegetation index (NDVI) to be collected from the Earth's land surfaces for over 20 years. Across the conterminous USA, a readily accessible and decade‐long data set is now available to study many aspects of vegetation activity in this region. One feature, the onset of deciduous plant growth at the start of the spring season (SOS) is of special interest, as it appears to be crucial for accurate computation of several important biospheric processes, and a sensitive measure of the impacts of global change. In this study, satellite‐derived SOS dates produced by the delayed moving average (DMA) and seasonal midpoint NDVI (SMN) methods, and modelled surface phenology (spring indices, SI) were compared at widespread deciduous forest and mixed woodland sites during 1990–93 and 1995–99, and these three measures were also matched to native species bud‐break data collected at the Harvard Forest (Massachusetts) over the same time period. The results show that both SOS methods are doing a modestly accurate job of tracking the general pattern of surface phenology, but highlight the temporal limitations of biweekly satellite data. Specifically, at deciduous forest sites: (1) SMN SOS dates are close in time to SI first bloom dates (average bias of +0.74 days), whereas DMA SOS dates are considerably earlier (average bias of −41.24 days) and also systematically earlier in late spring than in early spring; (2) SMN SOS tracks overall yearly trends in deciduous forests somewhat better than DMA SOS, but with larger average error (MAEs 8.64 days and 7.37 days respectively); and (3) error in both SOS techniques varies considerably by year. Copyright © 2002 Royal Meteorological Society.

Type of Medium: Online Resource

ISSN: 0899-8418 , 1097-0088

URL: Issue

URL: Article

DOI: 10.1002/joc.v22:14

DOI: 10.1002/joc.819

RVK:

RA 1000

Language: English

Publisher: Wiley

Publication Date: 2002

detail.hit.zdb_id: 1491204-1

SSG: 14

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